Multifrequency combined radio transmitter and receiver



Jan. 30, 1951 J. B. HARLEY ETAL 2,539,537

MULTIFREQUENCY COMBINED RADIO TRANSMITTER AND RECEIVERl 2 Sheets-Sheet 1 Filed April 29, 1949 w m w Jan; 30, 1951 Filed April 29, 1949 J. B. HARLEY ErAL MULTIFREQUENCY COMBINED RADIO TRANSMITTER AND RECEIVER 2 Sheets-'Sheet 2 /NVENTORS J. G. NORDAHL @www AT TOR/VE Y Patented Jan. 30, 11951 MULTIFREQUENCY COMBINED RADIO TRANSMITTER AND RECEIVER John B. Harley, Valley Stream, N. Y., and John G. Nordahl, Summit, N. J., assignors to Bell Telephone Laboratories,

Incorporated, New

York, N. Y., a corporation of New York Application April 29, 1949, Serial No. 90,374

(Cl. Z50-13) 3 Claims.

Another object is to reduce the number of`r adjustments to be made in coordinating the tuning of the transmitter and the receiver in combined transmitter and receiver sets.

A further object is to permit the establishment of a large number of operating frequencies by means of a relatively small number of piezoelectric crystals.

In superheterodyne transmitter-receiver sets it is necessary to tune different portions to different frequencies. When a large number of operating frequencies are used, it is generally necessary to make several adjustments in shifting from one frequency to another. A feature of this invention is and arrangement whereby the tuning of two heterodyne oscillators in the set to given frequencies simultaneously causes all the other tunable circuits of the transmitter and the receiver to be tuned to their proper frequencies. Another feature is the use of mechanically interconnected tuning controls to effect the tuning of the various parts of the system in coarse and ne steps, respectively.

The invention is particularly applicable to transmitter-receiver sets which utilize the same frequency for both transmitting and receiving. In applying the invention to a set of this character, wherein the operating frequency may be designated fo, two mixing oscillators are provided, one being a high-frequency oscillator of frequency f1, which is common to both transmitter and receiver, and the other an oscillator of lower frequency f2, which is a part of the transmitter. The high-frequency oscillator is crystal controlled and its frequency is adjustable over the operating range in l-megacycle steps only, by means of a switch which selects the proper crystal for the chosen carrier frequency. The crystalselecting switch is operated, either directly or indirectly, by a tuning knob provided on the panel. The frequency of the other oscillator is either continuously adjustable or adjustable in 0.1- megacycle steps, over a total range of 1 megacycle only, by means of a second tuning knob.

When transmitting, the voice-modulated waves of the transmitter oscillator are combined in a transmitter mixer with waves from the common high-frequency oscillator, and thesum frequency f1+f2=fo is selected for transmission. Before delivery to the antenna the sum frequency waves are amplified by a high-frequency power amplier. This amplifier is tuned to fo by the combined action of the two tuning knobs. The first knob, which selects the proper crystal, also tunes the amplifier in steps of l megacycle, the steps being governed by a-detent mechanism associated with this knob, but for fractions of a megacycle between these steps a fine adjustment is made by the second tuning knob, in a manner to be explained. If desired, the fractional adjustments may be limited to tenths of a megacycle by means of a detent mechanism associated with the second tuning knob.

When receiving, the incoming waves of frequency fn are first amplified by a radio-frequency amplifier tuned to this frequency. One of the features of the invention is that this amplifier is simultaneously tuned in its coarse adjustment, in l-megacycle steps, by the same control knob that effects the coarse tuning adjustment lof the transmitter high-frequency amplifier. After amplification, the waves are combined in a receiver mixer with waves from the high-frequency oscillator to obtain an intermediate frequency, this being the difference frequency fre-f1, which is the frequency f2 of the transmitter oscillator. The difference frequency waves are then amplified by an intermediate frequency amplifier tuned to f2, after which they may be detected in the usual manner, or, if desired, heterodyned down to a still lower intermediate frequency before detection, in which case a third mixing oscillator is provided. .Y Another feature of the invention is that the intermediate frequency amplifier is simultaneously tuned, over its 1-megacycle range, by the same control knob that tunes the low-frequency amplifier of the transmitter. Still another important feature is that the fine adjustment of the transmitter and receiver high-frequency amplifiers is simultaneously made by the same control knob that makes the fractional megacycle adjustment of the transmitter oscillator and the receiver intermediate frequency amplifier, this being accomplished by means of a system of interconnecting gears. The gearing is so designed, however, that the crystal selection is not affected by this fine adjustment. Thus the ultimate result is that all the tunable circuits of both transmitter and receiver are correctly tuned `to the operating frequency by the setting of the two controls.

The economy in the use of crystals which isv afforded by the invention is apparent when it is noted that only one crystal is required for each megacycle step. For example, in a model set designed and constructed to cover` a range from 20 to 28 megacycles with a frequency separation of 0.1 megacycle per channel, only eight crystals were required for the total of eighty channels.

The gearing system interconnecting the two tuning controls employed in the invention is the subject of a separate patent application, No. 720,222, filed January 4, 1947, by G. A. Boeck and E. J. Howard, Patent No. 2,479,465 granted August 16, 1949.

The invention may be more clearly understood from the following detailed description together with the accompanying drawings, of which Fig. 1 is a simplified diagram of one embodiment of the invention, and Fig. 2 is a more detailed .representation of another embodiment thereof.

Referring first to Fig. 1, there is shown in block form a combined radio transmitter and receiver system including antenna I, antenna V'relay 2, oscillator 3, receiver unit Il and transmitter unit 5. The receiver unit 4 comprisesradiofrequency ampiiier 6, :mixer V'1, intermediate frequency amplifier 8, and the audio frequency circuits 9 which include a detector, amplifier and loudspeaker, as indicated. The transmitter unit 5 comprises the audio frequency circuits I0 including a microphone, an amplifier and a modulator as indicated, the oscillator I I, mixer I2, vand radio frequency amplifier I3. Lines with arrows connecting the various blocks indicate the direction of energy flow. Oscillators 3 and II, amplifiers 6, 8 and I3, and mixers 'I and I2 are provided with variable reactance elements for tuning, which, for the purpose of this "description, may be taken to be variable condensers capable of adjustment by the rotating shafts I4, I5 and I6. Thus oscillator 3 is tuned by shaft I 4, amplifiers 6 and I3 and mixers 1 and I2 by shaft I5, and amplifier 8 and oscillator lIII by shaft I6.

Attached to shaft Ill rare 'control knob I1, detent I8, and bevel gear I9 which engagesvgear'ZO attached to shaft -2I. The detentmechanism I8 provides for a rotation of shaft 'I4 in steps. -Attached to shaft I6 are control knob 22 fandbevel gear 23 which engages gear 2li attached to Y'shaft 25. Gears 23 and 2li are reduction gears. 'Shafts I5, -2I and 25 are interconnected Vby differential gears 26, of proper ratios. Theg'earing system may be enclosed in a gear box as indicated yby 21.

In'addition to the tuning elements in oscillator 3, this unit is also provided with a vseries o-f frequency-*controlling crystals -28, selectable by switch 29 and shaft I4, so that thefo's'cillator frequency is variable in steps in accordance with the detent mechanism I8.

When transmitting, oscillator II is modulated by the output of the microphone, amplifier and modulator unit I0 in the usual manner. The modulated output of oscillator II is then fed into the transmitter mixer circuit I2, where 'it is combined with waves from the high frequency oscillator 3 to produce waves of the sum and 'difference frequencies. Waves of the sum frequency are selected and amplified by the radio frequency amplifier I3 and then delivered to the antenna I through the contacts of relay 2.

When the antenna I is switched to the receive position, the incoming signal is selected and amplifled by the receiver radio-frequencyamplier 6, which is tuned to the same frequency as the transmitter radio frequency amplifier I3 by means of shaft I5. The output of amplifier-6 is 4 combined in the receiver mixer 'l with waves from the high frequency oscillator 3 to produce waves of the sum and difference frequencies. Waves of the difference frequency are selected and amplied by the intermediate frequency amplifier 8, which is tuned to the Asame frequency as the transmitter oscillator Iii 'ibym'eans of shaft I6. The output of amplifier 8 is then changed to an .audible signal by the audio frequency circuits of block 9, viz., the detector, amplifier and loudspeaker.

To tune the set to the desired frequency, shaft I4 is rotated by means of knob Il to select the v`proper-crystal and 'tune the associated circuits of oscillator 3. 'The crystal frequencies are in onemegacycle steps, so'that in cooperation with the detent mechanism I8 the rotation of the shaft changes the oscillator frequency in increments of one megacycle. When shaft I4 is rotated it also rotates shaft I5 (but not shaft I6, as explained below) by equal-increments:through .gears lS'and 28 and differential .gears 26, so that the tuning rof the radio frequency amplifiers and lf3 and mixers 'I and I2 is also changed through on'ee megacycle increments. Thus by 'turning knob I'I the set may be tuned to the integral megacycle component of the desired frequency. Tofcomplete the tuning to thevfractional part of a megacycle, shaft I6 vis rotated by means of knob 22. The rotation of shaft I6 ltunes the intermediate frequency amplifier 8 of the receiver and the low frequency oscillator II of the transmitter through a total range vofvo'ne megacycle, so that by a fractional turn the tuning of these elements may be accomplished. As shaft f6 is rotated it also rotates shaft I5 '(but not shaft Il, which is held by 'detent I8) through reduction gears T23 and 24 and differential gears 26, and thus completes the tuning of the radio frequency ampliv ners 6 and I3 `and mixers VA'I and 12, to the required fraction of a megacycle. Control knob 22 may be provided with a detent lsimilar to detent I8 for facility Vin rapid tuning to designated increments of frequency, or the detent may be omitted, in 'accordance with Fig. rl, and shaft :I6 left lfree vto be set at -any point within its range of motion. Between shafts I6 an'dl there should be sufiicient gear reduction and friction to prevent motion being transmitted from shaft I5 to shaft I6, or the latter may be provided with a d'etentdevice to hold it in its adjusted position.

Another embodiment of thewinvention is illus'- trated in Fig. 2 which shows in some detail the essential elements lof a transmitter-receiver-set designed for frequency modulation. The electrical apparatus units atthe top of the diagram enclosed within the dashed lines 3l) are used primarily for reception, while those immediately below, enclosed within the dashed lines 3l are used for transmission. The com-mon antenna V32 may be connected tofeither the receiver or the transmitter by means of relay 3-3. Y

The Vunits enclosed within the dashed lines '35, including blocks 35, 36 land 37, 'comprise a high frequency beating oscillator which is used for both transmission and reception. Block 35 rep'- resents a crystal-controlled vacuum tube oscillator :and harmonic generator, and Aswitch 38 is -a switch for selecting one of the crystals 33 core responding to the desired frequency. Blocks 36 and 3'I are harmonic amplifiers in vtandem for amplifying theV outputffof 'oscillator v35.

Block AAll in the receiver is a radio frequency amplifier for received waves and block'lll is a first modulator or mixer lconnected to receive Waves from amplifiers 49 and 36. Block 42 is a. first intermediate frequency amplifier connected to the output of mixer 4|. Block 43 is a second mixer which receives the output of a second beating oscillator 44 and the output of amplifier 42 and delivers waves of the difference frequency to a second intermediate frequency amplifier and limiter unit 45. The output of this unit is delivered to the discriminator-detector 45, the output of which is amplified by audio amplifier 41, which is connected to loudspeaker 48. Block 49 repre'- sents a conventional noise amplifier and squelch circuit, the input of which is obtained from discriminator 46 and the output delivered to amplier 41.

In the transmitter unit 3|, block 59 represents a microphone or other audio signal source which is connected through block 5| to modulate the frequency of oscillator 52. Block 5| is a reactance tube control circuit which, in addition to its input signal from the signal circuit 59, receives a direct-current voltage from the output of the receiver discriminator circuit 45 to control the center frequency of oscillator 52, which covers the same range as the first intermediate frequency amplifier 42 of the receiver. The output of osciln lator 52 is combined in mixer 53 with waves from harmonic amplifier 31, and waves of the sum frequency are selected and delivered to the radio frequency power amplifier 54. From this amplifier the waves proceed to an antenna tuning unit 55 and thence to antenna 32 via antenna relay 33. When this relay is not energized the antenna is connected to the receiver amplifier 40.

By means of variable reactances certain units of the set in Fig. 2 are tunable, the reactances being represented on the drawing by a variable condenser for simplicity, such, for example, as condenser 56. tuning of these units may be thought of as being accomplished by the adjustment of such condensers, by means of rotating shafts. Thus shaft 51 tunes the units of the beating oscillator 34, viz., crystal oscillator 35 and harmonic ampliers 38 and 31. This shaft also operates crystal switch 38, so that the frequency adjustment of the units just mentioned is changed in steps. In like manner shaft 58 tunes mixer 53 and amplifier 54 in the transmitter, and mixer 4| and amplifiei` 4 in the receiver; shaft 59 tunes oscillator 52 in the transmitter, and oscillator 44 and amplifier 42 in the receiver; and shaft 89 adjusts the antenna tuning unit 55.

To shaft 58 are attached control knob 6| and dial 82, on which is engraved a scale 63. An index or pointer 64 is fixed to the movable detent 85, which engages dial 52 and which may be turned through asmall angle and thus rotate shaft 58 as will be presently explained. To shaft 59 are attached control knob 86 and dial 61, on which is engraved a scale 98. Pointer 89 and the detent 1 are fixed to the face plate 1|. The detent mechanism allows shaft 59 and dial 51 to rotate only in steps. If desired the detent may be made releasable to enable a dial setting at any intermediate position.

The tuning shafts 51, 58, 59 and 50 are interconnected by a system of gears. As will be explained later, the gearing is so designed that the rotation of shaft 58 when turned by knob 6| rotates shafts 51 and 69 but does not rotate shaft 59, while the rotation of shaft 59 imparts a limited motion to shafts 58 and 6D but does not rotate shaft 51.

Gears 12 and 13 are fixed to shaft 58 and ro- For purposes of description the tate with it. Gear 12 is a dierential sun gear which engages the differential planet gears 14 and 15; these rotate about the tie rods 19 which are fixed at one end to the face of the planetary arm gear 11, which rotates about shaft 58. Gears 14 and. 15 are meshed with the inner surface of the differential ring gear 18, which has attached to its outer rim the segment gear 19. The latter engages idler gear 80, which in turn engages the reversible idler gear 8|, which is meshed with gear 82. The last-named gear is not fixed to shaft 58, so that theshaft can be rotated when gear 82 is stationary. Gear 82 is connected with detent 85 by the tie rods 83 so that these two elements rotate together. In order to simplify the drawing, the supports for the shafts about, which gears 88 and 8| rotate are omitted, but may be ,considered as fixed to the frame of the set. The oscillator drive gear 84, fixed to shaft 51, is meshed with gear 11.

The antenna drive gear 13 attached to shaft 58 engages gear 85 which is fixed to shaft 89. Also xed to shaft 85 is a circular plate 81 in which are fixed the spaced adjusting screws 88 supporting an adjustable cam 89 composed of a series of links 90. Riding upon this adjustable cam and held in contact therewith by spring 9| is a slider 92 attached to rocker arm and drive gear 93. The latter is pivoted on pin 94 and drives gear 95 attached to shaft Si). Pivot 94 is shown unsupported, to simplify the drawing, but may be considered as being fixed to the frame of the set. Similarly, the end of spring 9| shown free in the drawing is also fixed to the frame.

Gear 96 is fixed to shaft 59 and engages one end of the geared rocker arm 91, which rocks about pivot 98, the support for which, not shown, is fixed to the frame of the set. The other end of the rocker arm is meshed with gear 92. The aforesaid gearing effects a reduction when transmitting motion from shaft 59 to gear S2 and shaft 58.

The radio set shown in Fig. 2 may, for example,

. cover the frequency range of 20 to 28 megacycles in 0.1-me-gacycle steps. The rotation of knob 6| causes the frequency of oscillaor 35 and the tuning of amplifiers 49 and 54, mixers 5| and 53, and antenna tuning unit 55 to change in steps of one megacycle, and the rotation of knob 68 causes the frequency of oscillators 52 and 44 and the tuning of amplier 42 to change in steps of 0.1 megacycle. The rotation of knob also causes a 0.1-megacycle adjustment to be made in the tuning of amplifiers 49 and 54, mixers 4| and 53, and antenna tuning unit 55. Thus by turning the two detented controls 6| and 58 the set can be quickly and accurately tuned, for transmitting or receiving, to any one of eighty channels differing by 0.1 megacycle.

To explain the operation and tuning of the set a specic frequency will be assumed, and its operation as a receiver will be considered first. Let F=Fi+F2 represent any incoming frequency in the operating range of the equipment (20 to 28 megacycles)` were F1 and F2 represent the integral and decimal portions of F, respectively. Taking F as 22.1 megacycles, for illustration, the high frequency control knob 5| is turned to set dial 62 at 22 (=F1), as indicated by pointer 94, and the low frequency knob 65 is turned to set dial 61 at .1 (=F2), as indicated by the fixed pointer 89. Thesame dial settings will also provide for transmission at the frequency 22.1 megacycles.

When control knob 6| is turned to 22 megacycles, the tuning condensers of receiver ampliascesa? .54 and mixer 5'3 are adjusted directly by' shaft 55 and tuned to a frequency of. 22 megacycles.

Since the low frequency control knob 56 (and shaft 55) isl held stationary by the detent mechanism 'I5 while control knob 6i is being turned, gear 8L' and hence ring gear 'L8 cannot turn. With ring gear 78 stationary, the planet gears 14 and l5 rotate around the inside of ring gear 18Y due to the motion of the differential sun gear l2, which is fixed to shaft 58. The planet gears 'i4 and 'i5 impart motion to gear Tl through the tie rod-s lo and thence tol shaft 51 through gear 84. By rotation ofshaft 5l the proper crystal is selected by crystal switch 38 and the tuning elements of the beating oscillator unit 34 are tuned to the proper frequency.

When the low frequency control knob 66 is turned to .l megacycle on dia-l 6l, the high fre'- quency knob 5i is held in the 22megacycle position by detent 55. Motion of the low frequency shaft 59 is imparted to gear 8'2 through the drive gear S5. and rocker arm 91. Through the tie rods Vi3 the rotation of gear 52 is imparted directly to the shell of the detent mechanism '55 on shaft 53. Since this detent mechanism is partially locked to sha-ft 5S through the detent arm of dial S2, shaft 55 is rotated through a small number of degrees and the condenser plates of the tuned circuits associated with shaft 53 are turned through an arc proportional to the frequency change impart-ed by the motion ofthe lo-w frequency knob 65. These circuits arev amplifiers 4d and 54, mixers il! and 53, and theA antenna tuning unit 55, which are now tuned by thisoperation t 22.1 megacyclesr Since the frequency setting of the high frequency oscillator 34 must remain fixed except as changed (in steps of one megacycle) by the high frequency knob E, i-t is necessary to provide that the turning of the low frequency knob 65 does not alter this setting by rotating shaft 5l. To this end the gear ratio of the idler gears 26 and 8i is selectedY so that any motion imparted to the differential ring gear 'i8 by gears 82, 8l and 80 will. exactly equal the motion imparted to it by the planet gears 'i4 and 'l5 due to the rotation of sun gear l2. As a result, the planet gears i4 andi 'lwill simply rotate about their shafts without imparting any motion to gear Tlv through theV i tie rods le, and hence nomotion will be transmitted from knob and shaft 59 to shaft 5l.

When the antenna relay 33 is not energized, the antenna 52 is connected for reception. A signal received by antenna 32 is amplified by the tuned. radio frequency amplifier 45. The output ofA this amplifier is fed into the first mixer 4I where it is combined with the output of harmonic amplifier 3S of the high frequency oscillator unit 34 to produce a variable intermediate frequency. As. previously stated, the high frequency mixing oscillator waves are obtained from a quartz crystal oscillator and a harmonic generator. Due to a limitation in the frequency range covered by highly stable quartz crystal oscillators, a crystal oscillator frequency was chosen which is a submultiple of the frequency desired for the beating oscillator. r'he proper crystal is selected by crystal switch 38, operated by shaft 5?. The desired harmonic of the crystal oscillator output is selected by the tuned harmonic amplifier 36, the tuning of which is also controlled by shaft 5l. This amplifier covers the frequency range from 15.55 to 22.55 megacycles, in steps of one megacycle. When dial 62 is turnedto 22 mega- 8 cycles, the harmonic amplier will be tuned to 11.55 megacycl'es. The output of amplifier 36 is used for reception, but when theequipmentis being used for transmission an` additional amplifier 3l is provided, since in this case a hig-he mixing voltage is desirable.

The output frequency of the receiver mixer 41 is the difference between the incoming carrier frequency of 22.1 mega'cyoles and the harmonic outputfrequency of 17;5'5 megacycles, or 4.55 megacycl'es. The 4.55-megfacycl`e signal is amplified by the tuned intermediate frequency amplifier 42, which maybe tuned over a frequency range from 4.45 to 5.45 megacycles. In order to obtain a greater degree of selectivity than could be 'achieved in a tuned intermediate frequency amplier of a relatively small number of tuned cir' cuits, the variable intermediate frequency i's heterodyned down to a lower frequency for amplification in a fixed-tuned intermediate fre'- quency amplifier in the following manner, as shown in the drawing (Fig. 2). The beating oscillator 45, tuned by knob S5 and shaft '59', covers the frequency range from 3.05 to L05 megacycles, and i's tuned in this particular case to 3.1'5 megacycles when the low frequency dial is set at .1. The 3.15-negacycle output of oscillatoi` 44 is combined with the 4.55-megacyole output of amplifier 42 in mixer 43 to produce a xed intermediate frequency of 1.4 megacycles, which is amplied and. limited by the fixed-tuned narrow band-pass amplifie-1' and limiter unit 45. The output of this unit is converted to an audio frequency by a suitable detector circuit, which in this case is the discriminator circuit 45 designed for frequency modulated signals. The output of the discriminator Vis fed into audio amplifier il and thence into the loudspeaker 48. The noise amplier and squelch circuit 49, which is of convene-l tional design, cuts olf the audio amplifier when no signal is being received.

When the antenna relay 33 is energized, the antenna 32 is connected for transmission. During transmission, the direct-current component of the output of the discriminator circuit 45, the magnitude of which is a function of the frequency difference between the intermediate frequency signal and the center frequency of the discriminator circuit, is applied to the reactance tube-s of the automatic frequency-control circuit 5! toco-rrect the frequency of the low-frequency transmitter oscillator 52. Since this oscillator is-also covering the same frequency range as the intermediate frequency amplifier 42 of the receiver, the outputof oscillator 52 is picked up through stray coupling by mixer 43 andV amplifier 45 (represented in the drawing by the dashed line connecting oscillator 52 and mixer 43) which are left connected during transmission to operate the automatic frequency control circuit 5I. The second receiver oscillator 44- andthe discriminator circuit 45 in this-way determine the frequency of transmission and reception rather than the less stable transmitter oscillator 52.r The transmitter oscilla-tor 52 is modulated by the same reactance tube control circuit 5! by a suitable connection of microphone 55. The output of oscillator 52, which covers the frequency range from 4.45 to 5.45 megacycles, and which inthe assumed case is 4.55 megacycles', is fed to the transmitter mixer 53.

In mixer 53 the 4.55-megacycle signal is combined with the 17.55-megacycle output of the harmonic amplifier 31, producing the desired carrier frequency of 22.1. megacycles. The outputlof the mixer is then amplified by the high frequency power amplifier 55. Since the output circuit of the transmitter must be accurately tuned to avoid loss in power, it is necessary to provide means for compensating for the impedance variations in the antenna circuit due to a change in frequency. This is accomplished by driving the antenna tuning condenser in unit 5.5 from shaft 58 through a motion imparted through slider 92 riding on the surface of the adjustable cam 89. The adjusting screws 8B supporting the links composing the cam are spaced at intervals corresponding to a frequency change of one megacycle, and are adjusted to properly tune the antenna by the motion transmitted to condenser shaft 60. The output of amplifier 54 is delivered to the antenna tuning unit 55, whence it is passed to antenna 32 via -Iflay 33.

' It is to be understood that the above-described arrangements are illustrative of the application of the principles of the invention. Other arrangements may be devised by those skilled in the art without departing from the spirit and scope of the invention.

What is claimed is:

1. In a combined radio transmitter and receiver arranged for transmission and reception of signals on carrier waves of the same frequency, a high frequency oscillator the frequency of which is adjustable in steps, a continuously variable low frequency oscillator, a first modulator for combining the waves from said oscillators to produce a transmitter wave of the sum frequency, and a first high frequency amplifier for amplifying said transmitter waves; a receiving circuit comprising a second high frequency amplifier, a second modulator for combining waves from said high frequency oscillator with the received waves to produce waves of the difference frequency, and an'intermediate frequency amplifier for amplifying said difference frequency waves; individual tuning means for each of said oscillators, modulators and amplifiers, a first common tuning control for simultaneously tuning said first and second high frequency amplifiers to the same frequency and said high frequency oscillator to another frequency, said control being adjustable in steps, a second common tuning control for simultaneously tuning said low frequency oscillator and said intermediate frequency amplifier to the same frequency, the frequency range of said second control being equal to one step of the said first control, and gearing means coupling said first and second controls for imparting a fine adjustment to said first and second high frequency amplifiers by the operation of said second control without disturbing the adjustment of said high frequency oscillator, said second control being unaffected by the operation of said iirst control.

2. In a combined radio transmitter and receiver arranged for transmission and reception of signals on carrier waves of the same frequency, a high frequency oscillator the frequency of which is adjustable in steps, a continuously variable low frequency oscillator, a first modulator for combining the waves from said oscillators to produce a transmitter wave of the sum frequency, and a first high frequency amplifier for amplifying said transmitter waves; a receiving circuit comprising a second high frequency amplifier, a second modulator for combining waves from said high frequency -oscil- 10 lator with the received waves to produce waves of the difference frequency, and an intermediate frequency amplifier for amplifying said difference frequency waves; individual tuning means for each of said oscillatorsmodulators and amplifiers; a coarse and fine two-adjustment frequency control device for simultaneously tuning said transmitter and receiver to the same frequency, said device comprising a first rotatable shaft for the control of said tuning means for said high frequency oscillator, a second rotatable shaft for the common control of said individual tuning means for said modulators and high frequency amplifiers, a first control knob fixed to said second shaft for rotating same, detent means enabling said second shaft to be rotated in steps and the frequency of said modulators and high frequency amplifiers to be adjusted in accordance with said steps, said detent means being rotatably supported on said second shaft and having a part secured to same, a planetary gear means supported on said second shaft and forming a power transmission means between said second shaft and said first shaft for the adjustment of said high frequency oscillator according to said steps, a third rotatable shaft for the common control of said individual tuning means for said low frequency oscillator and said intermediate frequency amplifier, the complete range of rotation of said third shaft causing a change in frequency of said last-mentioned oscillator and amplifier equal to one of said steps, a second control knob fixed to said' third shaft for rotating same, gear means comprising a rocker arm forming a power transmitting means between said third shaft and said detent means to transmit rotations of said third shaft to said second shaft, the gear ratio being such that the rotation of said third shaft through its entire range causes a change in frequency of said modulators and high frequency amplifiers equal to one of said steps, and holding means for said third shaft to prevent rotation of same by the rotation of said second shaft.

3. In a combined radio transmitter and receiver arranged for transmission and reception of signals on carrier waves of the same frequency, a high frequency oscillator the frequency of which is adjustable in steps, a continuously variable low frequency oscillator, a first modulator for combining the waves from said oscillators to produce a transmitter wave of the sum frequency, and a first high frequency amplifier for amplifying said transmitter waves; a receiving circuit comprising a second high frequency amplifier, a second modulator for combining waves from said high frequency oscillator with the received waves to produce Waves of the difference frequency, and an intermediate frequency amplifier for amplifying said difference frequency waves; individual tuning means for each of said oscillators, modulators and amplifiers; a first rotatable shaft for the control of said tuning means for said high frequency oscillator, a second rotatable shaft for the common control of said individual tuning means vfor said modulators and high frequency ampliners, a first control knob for rotating said second shaft, detent means rotatably supported on said second shaft and having a first part secured to said second shaft, a third rotatable shaft for the common control of said individual tuning means for said low frequency oscillator l1" and said intermediate `freqlfienny amplifier, .and a second .control 'knob 'for rotating, .said third shaft; gearingymeans .coupling said first, second and third shafts whereby 'the rotation of saidy second shaft by turning .sa-id -rst control knob transmits rotation to said rst :shaft but not toY said third shaft, and the rotation of Ysaid third shaft by turning vsaid second control knob transmits a lesser rotation :to said second shaft but no `rotationxto said first. shaft, saiid gearing means: .compri-sing a sun gear secured to said second shaft, a .ring gear rotatable relative to said sun gear, paired planet .gears in. mesh with said sun gear and saidring gear, a nrst Aplate gear carried on said-paired planetv gears and in driving connection with said first sha-ft, `a segment gear secured .to said ring gear, va seeond .plate gear carried .on a `second ilaartof said detent means, a train .ofr two idler gears interconnecting said second. plate: gear l.and said. seg-- ment gear, a rocker arm. inY gear connectionrwith said third shaft and said second plategearand operable to. rotate said second plate `gear and. to vhold saidY plate gear against rotation by the rotation of said ,second shaft.

JOHN B. HARLEY. JOHN G. NORDAHL.

REFERENCES ACITED The following references are .of record in the iile of this patent.:

UNITED STATES PATENTS 

